Symes ankle joint

ABSTRACT

The invention provides an artificial ankle joint particularly suitable for patients who have undergone the Symes amputation. An effective ankle pivot center is provided at substantially the natural position by the use of a pair of links pivoted to points on the metal sole plate of an artificial foot and points, spaced nearer together, on a stump socket.

United States Patent May Apr. 1, 1975 i 1 SYMES ANKLE JOINT 975.439 11/1910 Lawrence .1 3/32 l.l02,774 7/l9l4 M t' h k 3 34 [751 Memo" 5:"? kdonald 1.323,444 12/1919 t 333 g an [73] Assignee: J. E. Hanger & Company Limited, FOREIGN PATENTS OR APPLICATONS L d E l d 325,333 9/!920 Germany 4. 3/6 455,64l 2/1928 Germany 3/6 [22] Filed; May 28, 1974 [2]] Appl. No: 474,064 Primary E.\'aminerRonald L. Frinks Attorney, Agent, or Firm-Imirie, Smiley & Linn [30] Foreign Application Priority Data May 31 @973 United Kingdom 1. 25978/73 [57} ABSTRACT [52] U5. CL I I I I H 3/33 3/7 The invention provides an artificial ankle joint partic- {511 lm. CL ularly suitable for patients who have undergone the [58] Field ofgearch 3/3045 Symes amputation. An effective ankle pivot center is provided at substantially the natural position by the use of a pair of links pivoted to points on the metal {56] References Ci'ed sole plate of an artificial foot and points. spaced UNITED STATES PATENTS nearer together, on a stump socket 487,697 l2/l892 Ehle 3/33 7 Claims, 2 Drawing Figures QJEHTED APR 1 I975 SHEET 1 BF 2 PATENTEI] APR 1 i975 swear} 1 SYMES ANKLE JOINT This invention concerns improvements in artificial ankle joints. It is particularly but not exclusively directed to the provision of joints suitable for patients who have undergone the Symes amputation (disarticulation of the ankle); the joints also lend themselves to use with mono-tubular of skeletal modular legs and can accommodate appreciably longer below the knee stumps.

The Syrnes amputation results in a functionally good stump because the end of the stump is capable of taking the full weight of the patient. Prosthetic replacement, however. is difficult because of the small ground clearance. This is the distance between the end of the stump and the ground when the patient is standing level, and may be as little as one inch.

The patient has good control of the hip and knee, as these musculatures are not affected by this type of amputation. therefore patients are usually very active and require a robust device.

Devices in accordance with the invention make provision for an ankle joint to be supplied within the space of 1 inch from the base of the stump.

According to the invention we provide an artificial ankle joint comprising a metal sole plate within an artificial foot. the said sole plate carrying pivot bearings for a posterior upwardly and forwardly sloped swinging link and an anterior upwardly and rearwardly sloped swinging link. the said links being pivoted at their upper ends to posterior and and anterior lugs forming part of patient weight-bearing structure. and a pre-compressed resilient stress-relieving control block located between the sole plate and the weight-bearing structure.

The weight-bearing structure may be a stump socket or a plate fitted to the lower end of a modular leg. In either case its base may have a ground clearance of less than 30mm.

The swinging links may have an effective length less than 2()mm., the pivot bearings on the sole plate may have centres a little over lOOmm apart. while the lugs on the weight-bearing structure may provide pivot centres somewhat less than 80mm apart.

The locus of instantaneous centres of rotation of the joint. that is the points of intersection of the extended axes of the two links. forms an inverted hyperbola which passes through the two lower pivot centres and the effective ankle pivot at zero deflection.

The locus of the effective ankle pivot moves only about one-eighth inch over the range of Plant-aflexion to l2- doriflexion. This enables the effective ankle centre to be approximately I/4 inches up inside the stump (i.e. approximately at the level of the lateral maleolus. the natural ankle level).

At full dorsiflexion the instantaneous centre is back at the rear lower pivot and at full plantafexion it is in front at the forward lower pivot. The effective lever distances to the control rubber are great (compared with single axis ankle joints), the rubber loadings being thus relieved and reducing the stresses in the unit.

Two constructional forms of ankle joint are illustrated in the accompanying drawings, in which;

FIG. 1 is a vertical section through a joint suitable for a disarticulated ankle, and

FIG. 2 is a vertical section through a joint suitable for use with a modular leg.

In FIG. 1 the metal sole plate 1 carries posterior pivot bearing 2 and an anterior pivot bearing 3 carrying swinging links 4A and 48 respectively.

A stump socket 5 carries posterior and anterior lugs to which the upper ends oflinks 4A and 4B are pivoted.

A rubber block 6 is bonded to the plate 1 and is precompressed to bear against the base of the socket 5.

A balata toe spring assembly 7 is secured to the forward part of the plate 1 and a foamed plastic foot is moulded around the whole.

The locus of the instantaneous centres of rotation is indicated by the broken line 8.

In FIG. 2 like references denote like parts to those of FIG. 1. In the illustrated joint the stump socket 5 has been replaced by the modular leg fitting 10.

The fitting 11, shown in broken lines, is in the position requisite for attachment to a conventional ankle joint and demonstrates that a modular leg tube more than 2 inches longer can be accommodated by use of the linkage joint of the invention.

It will be understood that the invention is not restricted to the details of the preferred form which has been described by way ofexample which can be modified without departure from the broad ideas underlying them.

I claim:

1. An artificial ankle joint comprising a metal sole plate within an artificial foot, the said sole plate carrying pivot bearings for a posterior upwardly and forwardly sloped swinging link and an anterior upwardly and rearwardly sloped swinging link. the said links being pivoted at their upper ends to posterior and an anterior lugs forming part of patient weight-bearing structure, and a pre-compressed resilient stressrelieving control block located between the sole plate and the weight-bearing structure.

2. An artificial ankle joint according to claim 1 in which the weight-bearing structure is a stump socket.

3. An artificial ankle joint according to claim I, in which the weight-bearing structure is a plate fitted to the lower end of a modular artificial leg.

4. An artificial ankle joint according to claim 1, in which the instantaneous centres of rotation of the joint, namely the intersection points of the axes of the two links, forms an inverted hyperbola which passes through the two lower pivot centres and through the locus of the effective ankle pivot at zero deflection of the joint.

5. An artificial ankle joint according to claim 1, in which the length of each link is less than 30 mm.

6. An artificial ankle joint according to claim 1, in which the pivot bearings on the sole plate are more than 100 mm apart.

7. An artificial ankle joint according to claim I, in which the lugs on the weight-bearing structure are less than mm apart. 

1. An artificial ankle joint comprising a metal sole plate within an artificial foot, the said sole plate carrying pivot bearings for a posterior upwardly and forwardly sloped swinging link and an anterior upwardly and rearwardly sloped swinging link, the said links being pivoted at their upper ends to posterior and an anterior lugs forming part of patient weightbearing structure, and a pre-compressed resilient stressrelieving control block located between the sole plate and the weight-bearing structure.
 2. An artificial ankle joint according to claim 1 in which the weight-bearing structure is a stump socket.
 3. An artificial ankle joint according to claim 1, in which the weight-bearing structure is a plate fitted to the lower end of a modular artificial leg.
 4. An artificial ankle joint according to claim 1, in which the instantaneous centres of rotation of the joint, namely the intersection points of the axes of the two links, forms an inverted hyperbola which passes through the two lower pivot centres and through the locus of the effective ankle pivot at zero deflection of the joint.
 5. An artificial ankle joint according to claim 1, in which the length of each link is less than 30 mm.
 6. An artificial ankle joint according to claim 1, in which the pivot bearings on the sole plate are more than 100 mm apart.
 7. An artificial ankle joint according to claim 1, in which the lugs on the weight-bearing structure are less than 80 mm apart. 